CN1201560A

CN1201560A - Overcurrent protection circuit

Info

Publication number: CN1201560A
Application number: CN96197968A
Authority: CN
Inventors: H·达菲; C·怀恩; St·E·尼科尔斯三世; B·汤马斯
Original assignee: Raychem Corp
Current assignee: Raychem Corp
Priority date: 1995-09-14
Filing date: 1996-09-12
Publication date: 1998-12-09
Anticipated expiration: 2016-09-12
Also published as: JPH11512599A; DE69630608T2; EP0850505B1; US5689395A; KR19990044602A; EP0850505A1; CN1080476C; WO1997010637A1; ATE253780T1; DE69630608D1

Abstract

An overcurrent protection system which will give a rapid response to relatively small overcurrents. In a first aspect, the system can be connected between an electrical power supply (12) and an electrical load (26) to form an operating circuit. When so connected, the system protects the circuit from overcurrents, has a normal operating condition and a fault condition, and comprises: a circuit interruption element (24) having a normal state which permits the flow of a normal current, INORMAL, when the system is in the normal operating condition, and a fault state which permits the flow of at most a reduced current, substantially less than INORMAL, when the system is in the fault condition; and a control element (18), connected in series with the circuit interruption element (24), the control element having a variable resistance which is low when the current in the system does not exceed the normal current, INORMAL, by a predetermined current amount, and increases by at least a predetermined resistance amount when the current in the system exceeds the normal current, INORMAL, by the predetermined current amount; the circuit interruption element changing from its normal state to its fault state, thereby causing the system to change from its normal operating condition to its fault condition, when the resistance of the control element has increased by the predetermined resistance amount.

Description

Circuit overcurrent protection

The present invention relates to the overcurrent protection of circuit.The PTC circuit brake is known device.This device and load are arranged in series, are in a kind of low temperature, low-resistance state under normal operating state.Yet, if the electric current by the PTC device sharply increases, and/or PTC device ambient temperature on every side rises sharp, and/or holding time of normal running electric current surpassed the normal working time, the PTC device will be by " disconnection ", promptly be transformed into a kind of high temperature, high resistance state, thereby electric current is descended significantly.Even electric current and/or temperature return to its normal level, this PTC device still can maintain off-state usually, when the PTC device disconnects and cools off fully from power supply till.Practical PTC device comprises a PTC element that is made of the PTC conducting polymer, and it is a kind ofly to be disperseed or be distributed in a kind of graininess conductive filler synthetic of constituting of carbon black for example in the polymer by (1) organic polymer and (2).For example, in U.S. Pat 4237441,4238812,4315237,4317027,4426633,4545926,4689475,4724417,4774024,4780598,4800253,4845838,4857880,4859836,4907340,4924074,4935156, this PTC conducting polymer and the PTC device that comprises this polymer have been described in 4967176,5049850,5089801 and No. 5378407.

Normally used PTC protection device is subjected to a kind of restriction, if overcurrent is smaller, several times of normal current is for example only arranged, and the PTC device might need the long time just can be converted to off-state.

We have found that a kind of new-type over-current protection system, it can make quick response to smaller overcurrent.In this new-type system, the control element and the element that opens circuit are connected with load.Control element functionally is connected to the element that opens circuit, when the electric current in the circuit surpasses a predetermined value, control element detects overcurrent, and makes the element that opens circuit be converted to a kind of non-conductive relatively state (comprising the state that disconnects fully) from a kind of relative conduction state.

According to a kind of preferred version; the invention provides a kind of electrical system, it can be connected and constitute a function circuit between power supply and the electrical load, and the system of Lian Jieing has a kind of normal operating state and a kind of malfunction like this; can protective circuit prevent overcurrent, this system comprises:

A. element that opens circuit, it has

(1) a kind of normal condition when system is in normal operating state allows to flow through a normal current I _NORMAL, and

(2) a kind of malfunction when system is in malfunction at most only allows to flow through one and is significantly less than I _NORMALLittle electric current; And

B. control element that is connected with the element connected in series that opens circuit, control element has variable resistance, this control element

(1) electric current in system does not surpass normal current I _NORMALDuring a predetermined current amount, its resistance is very low, and

(2) if the electric current in the system has surpassed normal current I _NORMALA predetermined current amount, its resistance just increase a predetermined resistance value at least; When the resistance of control element increased a predetermined resistance value, the element that opens circuit was transformed into malfunction from normal condition, makes system be converted to malfunction from normal operating state.

Generally speaking, carry out following four kinds of functions, promptly detect electric current according to the circuit overcurrent protection that principle of the present invention constitutes, the blocking circuit, restriction sends the energy of circuit to, and with circuit and isolated from power.This circuit overcurrent protection can be considered to be made of some functional elements, finishes above-mentioned four kinds of excess current protective functions with these functional elements are collaborative.Fig. 1 a is several structured flowcharts of these functional elements to 1e.

Five functional elements representing in the 1e at Fig. 1 a are power supplys 102, control element 104, bypass elements 106, blocking element 108, and load 112.Power supply 102 provides power supply, the relevant function of load 112 executive circuits itself to circuit.Control element 104, bypass elements 106 and the 108 collaborative work of finishing overcurrent protection of blocking element.Control element 104 is generally carried out two kinds of functions such as energy that detection electric current and restriction send circuit under the situation of overcurrent.The function of electric current in the blocking element 108 general executions blocking circuit, and buffer circuit.Bypass elements 106 generally assists control element 104 restrictions to be sent to energy in the circuit by transfer current, makes blocking element 108 can interdict electric current in the circuit.

As shown in Fig. 1 a, some circuit overcurrent protection can comprise control element 104 and blocking element 108, but does not have bypass elements 106.In sort circuit, control element 104 can reduce the electric current in the circuit, makes blocking element 108 can interdict less current.As shown in Fig. 1 e, some circuit overcurrent protection can comprise control element 104 and bypass elements 106, but does not interdict element 108.In sort circuit, control element 104 and bypass elements 106 generally can reduce the electric current in the circuit significantly, but do not possess the circuit isolation features.

Fig. 1 a is a functional block diagram, the functional element that expression is made of the electric component in the circuit overcurrent protection of an embodiment of first aspect present invention.This circuit overcurrent protection of representing with total label 100 comprises four functional elements, and promptly power supply 102, control element 104, blocking element 108, and load 112.

Control element detects electric current, and determines whether the electric current that offers load 112 is in normal tolerance interval.Determined to offer the electric current of load 112 when excessive when control element 104, control element 104 just reduces the electric current in the circuit.By reducing the electric current in the circuit, control element 104 notices are interdicted elements 108, and order blocking element further reduces or stops to provide electric current to load 112.Control element 104 promptly detects overcurrent under overcurrent condition, and reduces overcurrent, thereby restriction sends the electric energy of circuit to, so that allow blocking element 108 to interdict the electric current that offers load 112 safely.

In the circuit structure of corresponding diagram 1a block diagram, the co-operation of control element 104 and blocking element 108 allows to select voltage and current specified than needed littler electric component in other structures.Because control element 104 is connected with blocking element 108, two elements all need can carry normal circuital current at least.Yet, the voltage quota of control element 104 can be more much lower than the normal voltage of circuit, and blocking element 108 should possess the ability of blocking maximum current under low-voltage, or can interdict normal voltage when low current, but need not interdict maximum overcurrent under normal voltage.When overcurrent took place, control element 104 had been unlikely to damage the degree that in the very short time of control element 104 electric current is reduced to be lower than the breaking current of blocking element 108.The voltage endurance capability of blocking element 108 can protect control element 104 can not bear overvoltage greater than the open circuit voltage of circuit when the blocking element is opened.

With Fig. 1 a in the corresponding circuit structure of the block diagram of 1d, the position of control element 104 and blocking element 108 can exchange, for example, the blocking element 108 in the circuit can be placed on control element 104 fronts.Yet, according to concrete circuit structure, bypass elements 106 still needs to be connected across (Fig. 1 b) on the control element 104, is connected across on control element 104 and the blocking element 108 (Fig. 1 c), or be connected across control element 104, in blocking element 108 and the load 112 (Fig. 1 d).

Fig. 2 a represents an embodiment of the first aspect of circuit overcurrent protection 10, has adopted a kind of structure of PTC device 18 and current detecting relay 14 and voltage detecting relay 22 in the drawings.Voltage detecting relay 22 is connected to the first winding point 24, and current detecting relay 14 is connected to the second winding point 16.In this circuit, the function of current detecting relay 14 is the electric currents in the testing circuit 10.When current detecting relay 14 detected overcurrent condition, current detecting relay 14 was just opened the second winding point 16, provides electric current to PTC device 18.Less than the resistance of voltage detecting relay 22, therefore, most of electric current is by PTC device 18 just often for the resistance of PTC device 18.The electric current of the resistance that increases PTC device 18 in just can restricting circuits 10, and the voltage of exerting pressure at voltage detecting relay 22 two ends.When the voltage at voltage detecting relay 22 two ends reached driving voltage detection relay 22 needed degree, voltage detecting relay 22 was just opened the first winding point 24, the electric current in the blocking circuit 10.Voltage detecting relay 22 is blocking relays, keeps open mode up to being reset after detecting and having interdicted overcurrent always.Current detecting relay 14 also is a blocking relay, or must be complementary with voltage detecting relay 22, only in this way, current detecting relay 14 just can not discharge and the closed second winding point 16 before voltage detecting relay 22 encourages fully and opens the first winding point 24.

The characteristics of this structure are that PTC device 18 was not comprised in the circuit before detecting fault.Therefore do not require PTC device 18 loaded current and response malfunction continuously.Therefore, this structure can be used for the occasion of circuit working electric current greater than the holding current quota of PTC device 18.For example, the PTC device 18 of 9.0 amperes of holding currents (for example Raychem RUE900 PolySwitch@ device) needs 10 to 90 seconds usually when the electric current of 18 amperes of responses.In the circuit structure of Fig. 2, if current detecting relay 14 original current responses are 18 amperes by norm, just can use smaller PTC device 18, RaychemRXE050 PolySwitch@ device for example, it at room temperature can respond 18 amperes impulse current within one second.

Circuit shown in Fig. 2 b is the coil position that has changed current detecting relay 14 in the circuit of Fig. 2 a.In this structure, current detecting relay 14 must be a blocking relay, because electric current can stop to flow when the second winding point 16 is opened.

The circuit overcurrent protection 10 of Fig. 2 c presentation graphs 2a, the circuit element correspondence that with dashed lines surrounds in the circuit overcurrent protection 10 four elements shown in Fig. 1 a, and promptly power supply 102, control element 104, blocking element 108, and load 112.

In some applications, be in the cable TV amplifier power supply of 1Hz for example in operating frequency, the selling at exorbitant prices of the AC current transformer that uses in the current detecting relay.Fig. 3 has represented an embodiment of the first aspect of circuit overcurrent protection 30, and this circuit is similar to the circuit of Fig. 2 a, and its difference only is that Hall effect device 38 of employing comes the electric current in the testing circuit.In this structure, with the electric current in Hall effect device 38 observation circuits 30, when detecting overcurrent, encourage a relay 42, open a winding point 44 of relay, current transfer is arrived PTC device 18.Other working methods of circuit are identical with the circuit of Fig. 2 a.Hall effect device 38 can be a kind of linear current probe or a promptly simple cheap again TTL transducer.Can be with a transistor, triac or other switching devices replace relay 42 and one winding point 44.

Electric component in the circuit shown in Figure 3 can be organized into groups according to the mode that is similar to Fig. 2 c, and Hall effect device 38 is included in the square frame of representing control element 104.

The circuit overcurrent protection that Figure 4 and 5 are represented is the present invention two embodiment on the other hand, and overcurrent wherein detects and realized by the current detecting relay.The circuit correspondence of Figure 4 and 5 the functional block diagram shown in Fig. 1 d.That part that is used for comprising the blocking element 108 shown in Fig. 1 d in the circuit of Figure 4 and 5 comprise by the parallel connection combination of PTC device 48 and the 4th winding point 46 and connect with the first winding point 24 combination.Described in U.S. Patent application (recording mechanism is 1570-US1), this series-multiple connection combination itself is exactly a contactor.

In the circuit overcurrent protection of Fig. 4, with the electric current in current detecting relay 14 testing circuits 50.Under overcurrent condition, the second winding point 16 is opened in 14 excitations of current detecting relay, and by voltage detecting relay 22 scattered currents.When 22 excitations of voltage detecting relay, its first winding point, 24, the three winding points 28 and the 4th winding point 46 are opened.The 3rd winding point 28 of connecting with the second winding point 16 plays the effect of contact for tripping, guarantees fully excitation of voltage detecting relay 22.By the parallel connection of the 4th winding point 46 and PTC device 48 combination and with the combination of connecting of the first winding point 24 electric current on the disconnecting consumers 26 safely.When the 4th winding point 46 and the first winding point 24 began to open, the 4th winding point of opening 46 was diverted to PTC device 48 with electric current.The first winding point 24 might produce electric arc when opening, yet, the very fast formation high impedance of PTC device 48 meetings, thus make electric current drop to certain value, make first winding point can interdict the electric current of load 26.

A shortcoming of circuit shown in Figure 4 is to have small electric current in resistance 32 always, therefore, and can consumed power and heating in the circuit normal work period.Circuit overcurrent protection 70 shown in Figure 5 does not need this resistance 32.In the circuit of Fig. 5, when current detecting relay 14 detects overcurrent, just excitation of current detecting relay 14, its second group of normal opened contact 16 closure is by voltage detecting relay 22 scattered currents.Voltage detecting relay 22 is encouraged, its 3rd group of normal opened contact 28 closure, and first group of normally closed contact 24 and the 4th group of normally closed contact 46 are opened.28 closures are put in the 3rd winding, make voltage detecting relay 22 keep excitation, and the first winding point 24 and the 4th winding point 46 are opened, the electric current that cuts off load 26 resembling among Fig. 4.

The circuit overcurrent protection of representing among Fig. 6 90 is embodiment of third aspect present invention, adopts Hall effect device 38 to come detection of excessive current therein, and the action of control relay 42, opens the first winding point 24 and the 4th winding point 46 by relay 42.In this embodiment, the first winding point 24 can be deferred to the 4th winding point 46 always and open after opening again, and this delay depends on how long PTC device 48 needs just can be converted to high resistance state.

Claims

1. electrical system, it can be connected and constitute a function circuit between power supply and the electrical load, and the system of Lian Jieing has a kind of normal operating state and a kind of malfunction like this, can protective circuit prevent overcurrent, and this system comprises:

A. element that opens circuit, it has

(1) a kind of normal condition when this system is in normal operating state allows to flow through a normal current I _NORMAL, and

(2) a kind of malfunction when this system is in malfunction at most only allows to flow through one and is significantly less than I _NORMALLittle electric current; And

B. control element that is connected with the circuit breaker element connected in series, this control element has variable resistance, this control element

(1) electric current in this system does not surpass normal current I _NORMALDuring a predetermined current amount, its resistance is very low, and

(2) if the electric current in this system has surpassed normal current I _NORMALA predetermined current amount, its resistance just increase a predetermined resistance value at least; When the resistance of this control element increased this predetermined resistance value, this element that opens circuit was transformed into malfunction from its normal condition, makes system be converted to malfunction from its normal operating state.

2. according to the system of claim 1, it is characterized in that this control element comprises following tandem compound:

A. current sensing means, it has:

(1) electric current in this system does not surpass this normal current I _NORMALBe in the turn-off current state during this predetermined current amount, and

(2) electric current in this system has surpassed this normal current I _NORMALBe in the current excitation state during this predetermined current amount; And

B. combination in parallel, it comprises

(1) be connected to first contactor of this current sensing means, first contactor wherein exists

Closure when (a) this current sensing means is in the turn-off current state, and

(b) when being in the current excitation state, opens this current sensing means,

(2) voltage check devices, it has

Be in the off voltage state when (a) voltage at these voltage check device two ends does not have to surpass the voltage of a scheduled volume, and

Be in the voltage drive state when (b) voltage at these voltage check device two ends has surpassed the voltage of this scheduled volume, and

(3) PTC devices, preferably a polymer PTC device.

3. should it is characterized in that according to the system of claim 2:

A. this current sensing means comprises a current detecting relay coil; And

B. this first current switch comprises first winding point that is connected to this current detecting relay coil.

4. according to the system of claim 2, it is characterized in that:

A. this current sensing means comprises

(1) has the current sensor of an output; And

(2) be connected to the relay coil of the output of this current sensor; And

B. this first contactor comprises first winding point that is connected to this relay coil.

5. according to the system of claim 4, it is characterized in that this current sensor comprises a Hall effect device.

6. according to the system of one of claim 2 to 5, it is characterized in that:

A. this element that opens circuit comprises the second circuit switch that is connected to this voltage check device; And

B. this second circuit switch

(1) when this voltage check device is in the off voltage state, be closed, and

(2) when being in the voltage drive state, voltage check device is opened.

7. according to the system of claim 6, it is characterized in that:

A. this voltage check device comprises a voltage detecting relay coil; And

B. this second circuit switch comprises second winding point that is connected to this voltage detecting relay coil.

8. according to the system of claim 1, it is characterized in that this control element comprises following tandem compound:

A. current sensing means, it has

(1) electric current in this circuit does not surpass this normal current I _NORMALBe in the turn-off current state during this predetermined current amount, and

(2) electric current in this circuit has surpassed this normal current I _NORMALBe in the current excitation state during this predetermined current amount; And

B. combination in parallel, it has

(1) be connected to first contactor of this current sensing means, first contactor exists

Closure when i. this current sensing means is in the turn-off current state, and

Ii. when being in the current excitation state, opens this current sensing means, and

(2) PTC devices, preferably a polymer PTC device.

9. according to the system of claim 8, it is characterized in that this element that opens circuit comprises the second circuit switch that is connected to this current sensing means, above-mentioned second circuit switch:

A. closure when this current sensing means is in the turn-off current state; And

B. when being in the making current state, opens this current sensing means.

10. according to the system of claim 8 or 9, it is characterized in that:

A. this current sensing means comprises

(1) has the current sensor of an output; And

(2) be connected to the relay coil of the output of this current sensor; And

B. this first contactor comprises first winding point that is connected to this relay coil; And

C. this second circuit switch comprises second winding point that is connected to this relay coil.

11., it is characterized in that this current sensor comprises a Hall effect device according to the system of claim 10.

12. a circuit comprises:

A. power supply;

B. electrical load; And

C. according to the electrical protection systems of one of claim 1 to 11.

13. an electrical system, it can be connected and constitute a function circuit between power supply and the electrical load, and the system of Lian Jieing has a kind of normal operating state and a kind of malfunction like this, can protective circuit prevent overcurrent, and this system comprises:

A. element that opens circuit, it has

(1) a kind of normal condition when this system is in this normal operating state allows to flow through a normal current I _NORMAL, and

(2) a kind of malfunction when this system is in malfunction at most only allows to flow through one and is significantly less than I _NORMALLittle electric current;

B. control element that is connected with this element connected in series that opens circuit, and

(1) electric current in this system does not surpass this normal current I _NORMALDuring a predetermined current amount, have a control element off state, and

(2) if the electric current in this circuit has surpassed this normal current I _NORMALThis predetermined current amount just enters the control element energized condition;

C. with a bypass elements of following tandem compound parallel connection

(1) this control element,

(2) this element that opens circuit, and

(3) this load

And have

(1) a kind of bypass off-position only allows a little by-pass current by this bypass elements at most, and

(2) a kind of bypass energized condition allows a by-pass current that obviously increases by this bypass elements; And when this bypass elements when the bypass off-position is converted to the bypass energized condition, this element that opens circuit is converted to malfunction from normal condition, and, when this control element when the control element off-position is converted to the control element energized condition, this bypass elements is converted to the bypass energized condition from the bypass off-position, thereby makes this circuit be converted to malfunction from normal operating state.

14., it is characterized in that this control element comprises a current sensing means according to the system of claim 13:

A. the electric current in this system does not surpass normal current I _NORMALIt is in a kind of turn-off current state during this predetermined current amount; And

B. the electric current in circuit has surpassed normal current I _NORMALDuring this predetermined current amount, it is in the current excitation state.

15., it is characterized in that this bypass elements comprises following tandem compound according to the system of claim 14:

A. resistance; And

B. following parallel connection combination

(1) voltage check device:

A. when the voltage at these voltage check device two ends was lower than predetermined voltage, it was in a kind of off voltage state, and

When b. the voltage at these voltage check device two ends surpassed this predetermined voltage, it had a kind of voltage drive state, and

(2) Yi Xia tandem compound

(a) be connected to first contactor of this current sensing means, it

(i) closure when this current sensing means is in the turn-off current state, and

(ii) when being in the current excitation state, opens this current sensing means, and

(b) be connected to the second circuit switch of this voltage check device, it

(i) closure when this voltage check device is in the off voltage state, and

(ii) when being in the voltage drive state, opens this voltage check device.

16., it is characterized in that this element that opens circuit comprises following tandem compound according to the system of claim 15

A. be connected to the tertiary circuit switch of this voltage check device, it

(1) closure when this voltage check device is in the off voltage state, and

(2) when being in the voltage drive state, opens this voltage check device, and

B. following parallel connection combination

(1) be connected to the 4th contactor of this voltage check device, it

(a) closure when this voltage check device is in the off voltage state, and

(b) when being in the voltage drive state, opens this voltage check device, and

(2) PTC devices.

17. the system according to claim 15 or 16 is characterized in that

A. this current sensing means comprises a current detecting relay coil; And

B. this first contactor comprises first winding point that is connected to this current detecting relay coil.

18. the system according to claim 15 is characterized in that

A. this voltage check device comprises a voltage detecting relay coil;

B. this second circuit switch comprises first winding point that is connected to this voltage detecting relay coil; And

C. this tertiary circuit switch comprises second winding point that is connected to this voltage detecting relay coil.

19., it is characterized in that this bypass elements comprises following tandem compound according to the system of claim 14:

A. voltage check device,

(1) when the voltage at these voltage check device two ends was lower than a predetermined voltage, it was in a kind of off voltage state, and

When (2) voltage at these voltage check device two ends surpassed this predetermined voltage, it was in a kind of voltage drive state; And

B. following parallel connection combination

(1) be connected to first contactor of this current sensing means, it

I. when being in the turn-off current state, opens this current sensing means, and

Closure when ii is in the current excitation state at this current sensing means

(2) be connected to the second circuit switch of this voltage check device, it

I. when being in the off voltage state, opens this voltage check device, and

Ii. closure when this voltage check device is in the voltage drive state.

20., it is characterized in that this element that opens circuit comprises following tandem compound according to the system of claim 19

A. be connected to the tertiary circuit switch of this voltage check device, it

(1) closure when this voltage check device is in the off voltage state, and

(2) when being in the voltage drive state, opens this voltage check device; And

B. following parallel connection combination

(1) be connected to the 4th contactor of this voltage check device, it

(a) closure when this voltage check device is in the off voltage state, and

(b) when being in the voltage drive state, opens this voltage check device, and

(2) PTC devices.

21. the system according to claim 19 is characterized in that

A. this current sensing means comprises a current detecting relay coil; And

22. the system according to claim 19 is characterized in that

A. this voltage check device comprises a voltage detecting relay coil;

23. a circuit comprises:

A. power supply;

B. electrical load; And

C. according to the electrical protection systems of one of claim 13 to 22.